RU2255192C2 - Inflatable frame structure - Google Patents

Abstract

FIELD: building, particularly temporary fast-erection inflatable structures of increased dimensions adapted to serve in all conditions including extreme ones and in all climatic zones.

SUBSTANCE: structure comprises pneumatic frame formed of support inflatable balloon contour arranged along structure periphery, inflatable balloons arranged in other horizontal structure planes and connected with inflatable members of post or arch types arranged in vertical planes and with inflatable members defining door openings. Inflatable frame is fully covered with elastic material awning and has means for structure dimension change. Inflatable frame and awning have at least one horizontal cut plane dividing the frame and awning at least into two layers. Means for structure dimension change is made as a system of inflatable frame and awning components detachably joined one to another during cooperation thereof. The components are arranged in horizontal plane area and located along the full cut plane perimeter. The fist parts of the components are connected to upper part of lower layer, the second ones are connected to lower parts of upper layer, wherein perimeter of upper part of lower layer and perimeter of lower part of upper layer equal thereto is less or equal to the structure base perimeter. Cut plane is located at least in one structure part, preferably in central one.

EFFECT: reduced labor inputs during structure production and erection, provision of transportable structure parts and possibility to perform temporary works inside the structure with the use of hoisting equipment inside it.

7 cl, 19 dwg

Description

The invention relates to temporary prefabricated pneumatic frame-sized structures, large in area and height, adapted for operation in various conditions, including in extreme and in any climatic zones.

Such structures can be used as temporary shelters for large industrial, agricultural, sports, and other national and military facilities using bulky lifting equipment, for example, to open radioactive waste burials and extract cranes from bunkers, wells, and trenches of bulky closed containers with them loading them onto vehicles inside the structure to relocate their location.

Pneumatic frame constructions are also used as administrative buildings to accommodate people, equipment repair workshops for repair work in the field, as warehouses, exhibition halls, entertainment and sports facilities, as temporary barracks, command posts, decontamination points (decontamination, disinfection) and in all other cases when it is necessary to quickly provide an ideal “roof over your head”.

Pneumoframe constructions were more often used as field hospitals to provide emergency medical care to victims of natural disasters, accidents, catastrophes and other emergency situations, including and in inaccessible places and remote areas. These structures are special mobile medical facilities, the structure of which includes up to a dozen or more separate blocks, which provide all the technological processes for organizing medical care.

There was a need for the use of pneumatic frame structures for carrying out spraying (painting, etc.) of various compositions on large-sized structures within their work with restricting the spread of toxic or aggressive applied material to the dimensions of the pneumatic frame structure.

At the same time, when inoperative, such structures should be packed in light bales that are convenient for transportation, including and air transport.

A number of designs of pneumatic frame structures are known, for example, according to French patent No. 1372039, IPC E 04 N or Italian patent No. 563843, IPC A 45 F, “Advanced tents with an inflatable frame” have a pneumatic frame consisting of arches and pneumatic jumpers connecting them and support cylinders. Tents have a double roof and valves for inflation of the frame. Although the design of a large tent satisfies most of the operational requirements for such structures, its drawback is the inability to connect such tents to create a single structure with a network of working areas connected by a common passage, for example, a structure that includes a number of separate blocks necessary for the development of the structure with an increase in area. In addition, tents are designed to serve mainly people and have limited height dimensions, which does not allow the use of large-sized lifting equipment such as truck cranes inside the structure.

The development of the structure by area in the technical solution according to the patent of the Russian Federation No. 2041332, IPC E 04 Н 15/20, “Air support structure” is ensured by the presence of a longitudinal sliding part due to adjacent sections, supplementing which, you can increase the area of the structure.

But such a technical solution has, at a minimum, the same disadvantages as the solution of French patent No. 1372039.

The most advanced in structural solutions, in terms of comfort, compliance with operational requirements, and the ability to develop a structure over an area in various directions is the “Pneumatic frame quick-erect structure” according to the RF patent No. 2134761, IPC E 04 H 7/20, the working module of which can be taken as a prototype to the proposed solution.

Such a structure consists of separate modules, and each of which performs its own functional purpose. The main one of the modules is the worker, which occupies most of the area of the entire structure and provides the basic technological operations depending on the purpose of the structure.

The pneumoframe structure provides in a more complete way the creation of branched systems of modules located both in the longitudinal, transverse and parallel directions to each other, allowing you to fit into the surrounding terrain for compact placement of the structure in a limited territory when you deploy it.

The working module of such a structure is made in the form of a pneumatic frame, consisting of arches located in vertical planes along the structure and resting on supporting cylinders in the horizontal plane, and longitudinal cylinders inseparably connected with them in other horizontal planes, while a sealed elastic frame is located on the outer surface of the pneumatic frame the shell is an awning, and the end surfaces of the structure in the area of the end arches and doorways have devices for possible changes in overall dimensions armament of embodied as detachable flexible ties, which are part of the power module docking assembly together, wherein the sealing portion in the form of connection of the apron of flexible material web overlaps the top portion of the docking force around the perimeter zone abutting arcs.

A pneumatic frame construction according to the patent of the Russian Federation No. 2134761, having a device to enable the possibility of changing the overall dimensions on all types of modules, including and at the worker, it effectively solves the developmental problem of the structure by area, but at the same time, the overall dimensions for the height of such a structure are limited to 2.5-3 meters, approximately at the level of the size of stationary residential premises. In this case, the manufacturability of each module during its production and testing, and transportability, and the deployment of modules during operation without the use of lifting equipment are also ensured.

The disadvantage of the design of the working module of such a structure is that inside the structure, the height dimensions do not allow the use of large lifting equipment. The manufacture and testing of the finished product of such a pneumatic frame structure with a large height within 5.5-6.2 m becomes practically impossible in most production buildings of manufacturers, since the existing height of such rooms does not allow filling the frame of the gluing structure, for example , awning, to check for leaks, etc.

The technical problem solved by the invention consists in creating a pneumatic frame structure that performs the function of temporarily sheltering work areas using large-sized hoisting equipment inside while reducing the complexity of manufacturing and installation of the structure and maintaining its good transportability.

The technical result is achieved by the fact that the pneumatic frame structure consists of a pneumatic frame formed by the contour of the supporting inflatable balloons around the perimeter of the structure, inflatable balloons located in other horizontal planes of the structure, connected to inflatable elements such as pillars or arches located in vertical planes, and with inflatable elements , limiting the doorways, and the entire pneumatic frame is covered with an elastic material forming an awning, and has a device for changing the size total dimensions of the pneumatic frame structure.

Distinctive features from the closest analogue (prototype) is that the pneumoframe and tent are made height-based in at least one horizontal plane of the connector, dividing them into at least two tiers, and the device for changing the overall dimensions of the structure is made in the form of a detachable system joined during the interaction of the parts of the nodes of the pneumatic frame and tent, located in the horizontal plane around the entire perimeter of the connector, one part of each of which is attached to the upper part of the lower tier, The second part of - the top-tier bottom, the perimeter of the top of the lower tier and equal to it around the bottom of the upper tier is made smaller than or equal to the perimeter of the pneumatic structures in the bottom of it and the connector is located, at least in part of a structure, preferably in the center.

The connector dividing the structure into two tiers is formed between two congruent circuits of inflatable balloons located in horizontal planes around the entire perimeter of the connector, the first of which is connected inextricably with the pillars of inflatable balloons and with supporting cylinders and completes the pneumatic frame of the lower tier separately filled with air, and the second is formed by supporting cylinders of the upper tier and is inseparably connected with the upper parts of the inflatable struts or arches and with other inflatable cylinders of this tier, filled separately from the pneumatic rkasa lower tier. Detachable interconnecting nodes for connecting the tiers to each other are located on each congruent circuit of the cylinders mounted on top of each other and include the power and sealing parts, while the power part is made in the form of flexible tightening up to full contact along the entire perimeter of the contacting congruent contours of both tiers of detachable couplers, and one rug of detachable couplers is located around the perimeter on the upper, final contour of the lower tier, mainly in the area of the inflatable racks, and the second half is on the congre a vent loop along the perimeter of the lower support cylinders of the upper tier, opposite the first half of the detachable couplers of the lower tier. The sealing part is made in the form of a docking apron from an elastic panel, which is a continuation of the tent of the upper tier, overlapping the power part of the dock in the connector area along the entire perimeter, while the lower edge of the apron has fasteners for attaching to the panel of the tent of the lower tier

In one embodiment, the pneumoframe and awning, at least only in the part of the structure, mainly in the central, in the same horizontal plane of the connector, dividing them into at least two tiers, are made integral in height, and the construction of the connection of the nodes of the upper and lower tiers is similar to that described above.

For individual cases of operation, at least one section can be made in the lower or upper tier between the two horizontal contours closest in height along the entire perimeter, limited by inflatable balloons and sections of inflatable struts or arcs, insulated by filling due to internal partitions of inflatable struts or arcs from adjacent sections of the tier, and in an unfilled state, the sections of this section are laid by rolling between the inflatable horizontal contours that have become the closest in height from inflatable balloons, which contact each other through an unfilled section of the section and are secured with detachable mating nodes, similar to detachable mating nodes located in the zone of separation of the structure into tiers.

The following dimensional parameters are optimal for the pneumoframe structure, the ratio of the heights of the lower and upper tiers is selected in the range of 0.8-1.2; the diameters of the inflatable support cylinders, racks or arches of the upper tier carcass are chosen equal to or smaller than the diameters of the inflatable support cylinders, racks of the lower tier; inflatable racks of the lower tier are located to a horizontal plane inside the structure at an angle of 90 ° or less.

At least the individual arches of the upper tier have inner horizontal elastic stretch marks in the upper part.

Other technical solutions of devices for changing the dimensions of a pneumatic frame structure by area are also used in patent publications, for example, in RF patent No. 2171344, such a change can also be achieved through a system of tambours on the side surface of the structure, with elastic ties installed around the perimeter of the tambour inflatable arch, also performing the role of the power part of the docking station.

Temporary building according to copyright certificate No. 997790, IPC E 04 B 1/343 can be used as a portable shelter for large, including height objects, such as high-speed vessels, however, pneumatic arched sections made of airtight technical fabric are connected between a large number of rigid elements - crossbars, braces, pins, eyes, support sections, etc. These rigid connections keep the arched sections from both longitudinal and transverse displacements relative to each other, but interfere with the compact and reliable installation of the structure during transportation to the place of operation and complicate the installation of the structure. Changing the dimensions for the height of the structure is not provided for in the design.

The certificate of authorship No. 767302, IPC E 04 B 1/345 provides for a change not of a pneumoframe, but of a spherical air-support shell due to the presence of two rows of meridially arranged loops and a rope passed alternately through the rows with their subsequent pulling together and the formation of a meridial fold of the shell. Thus, choosing the required size of the air support structure, connect the corresponding sections with an assembly seam, forming a sealed fold, change the volume dimensions of the structure, but not the dimensions along the height of the structure.

To overlap significant unsupported spaces, for example, the design “Shelter for aircraft” is used according to the copyright certificate No. 853029, IPC E 04 B 1/345. Although this technical solution includes rigid wall fencing and a coating of balloons filled with gas lighter than air, for example, helium, connected by holding cables to the supporting elements of the shelter, it contains a device for adjusting the installation height of the coating. The aerostatic coating is held and moved along the height-guiding ropes by means of drives with drums for winding the holding ropes. In connection with the possibility of changing the height of the building during operation, the opportunity is created to save energy for heating the hangar. But this solution is applicable only to the rigid structures of buildings, in practice, the balloon cylinders are made rigid and the regulation system as a whole is complex.

Since in the scientific, technical and patent literature no technical solutions were found with the distinguishing features indicated above in the materials of the application for the proposed invention, that is, there are no technical solutions for dividing pneumoframe structures into tiers in height with the provision of mounting the structure with self-lifting and detachable connection of tiers among themselves with the help of flexible locking devices, there are no solutions to regulate the height of the structure by disabling individual sections of the upper or lower tier, then false decision can be considered new.

A comparative analysis of the invention with identified analogues also confirms that the proposed design of the pneumoframe structure is new. The whole set of features of the invention does not follow for experts explicitly from the prior art, therefore, the claimed device meets the criteria of an inventive step. The invention is industrially applicable because it allows to achieve a technical result.

The essence of the invention is illustrated by the accompanying drawings, where

figure 1 shows a General view of the pneumoframe structure rectangular in plan;

figure 2 - a in figure 1;

figure 3 is a view of B in figure 1 with a partially removed outer shell-awning;

figure 4 - node In figure 1 - diagram of the docking node - connection congruent circuits of the first and second tiers;

figure 5 is a cross section GG in figure 4 is a connection of tiers;

in Fig.6 is a view of D in Fig.5;

in Fig.7 is a cross-section EE in Fig.3 is a vertical section along the doorway;

in Fig.8 is a section FJ in Fig.3 is a horizontal section along the doorway of the structure;

figure 9 is a variant of the mounting scheme of the internal elastic stretch marks between the pneumatic frame arches in the upper part of the upper tier;

figure 10 is a view of B in figure 1 is a variant with an unfilled upper section of the lower tier, located between the tiers;

in Fig.11 - section 3-3 in Fig.10 - connection of the upper and lower tiers with the placement between them of an unfilled upper section of the lower tier;

in Fig.12 is a General view of the pneumoframe structure of the tent-type octagonal in terms of shape;

in Fig.13 is a top view of the pneumoframe structure of the tent type in Fig.12 octagonal in terms of shape;

in Fig.14 is a section II from Fig.12 is a diagram of a docking unit for connecting congruent circuits of the first and second tiers of a tent-type pneumoframe structure with congruent cylinders of the upper tier diameter smaller than the diameter of the congruent cylinders of the lower tier;

on Fig is a General view of the pneumatic frame structure of the tent type with the location of the second tier above the Central part of the structure;

in Fig.16 is a top view of the pneumoframe structure of the tent type in Fig.15;

on Fig - section KK in Fig.16;

on Fig is a General view of the pneumoframe structure rectangular in plan view, consisting of three tiers;

on Fig - axonometric view of the pneumoframe structure rectangular in plan view - the arrangement of the cylinders in the upper and lower tiers.

The pneumoframe structure in a rectangular shape in plan consists of a pneumatic frame of the lower tier 1 and a pneumatic frame of the upper tier 2. The pneumatic frame of the upper tier is formed in horizontal planes by longitudinal inflatable balloons 3, the contour of the support cylinders 4 and in vertical planes by inflatable transverse arches 5, located as along the ends of the structure along with end inflatable balloons 6, limiting the doorways, and along the structure with a certain step, providing a small tion average number of arcs per meter length of the construction. The entire pneumoframe of the upper tier is covered with an elastic material forming an awning 7.

Under the pneumatic frame of the upper tier 2 there is a pneumatic frame of the lower tier, consisting of longitudinal inflatable balloons 8, a contour of supporting cylinders 9 of the lower tier in horizontal planes and parts of the inflatable struts-arches 10, coaxial with the corresponding arches of the upper tier 5, also located at the ends of the structure, and along the structure. The entire pneumatic frame of the lower tier is also covered with an elastic material forming an awning 11, and the awning can be located not only along the outer contour of the pneumoframe, but also along the inner contour.

For two-tier structures, such separate dimensions are preferable: the ratio of the heights of the lower and upper tiers in the range of 0.8-1.2, the diameter of the inflatable support cylinders of the uprights or arches of the upper tier frame is equal to or less than the diameter of the inflatable support cylinders, the racks of the lower tier frame, and inflatable racks of the lower tier are located to the horizontal plane inside the structure under the corner of 90 ° or less.

The pneumoframe structure contains a device for changing its overall dimensions, in particular, changing the height in height, made in the form of a system of detachably joined nodes 12 of the pneumoframe and docking nodes of the awning 13 located in the horizontal plane along the entire perimeter of the tier connector, one part 14 of each of which attached to the upper part of the lower tier, and the second part 15 of them - to the lower part of the upper tier When the parts (elements) of detachably joined nodes interact, a reliable connection of the lower and upper tiers.

The system of detachably joined pneumatic frame nodes can be performed on each arch or stand in the zone of the tier connector, i.e. one part of the node 14 on each of the racks of the upper part of the lower tier interacts with another part 15 located on each of the arches of the lower part of the upper tier, or each pair of pneumatic frame elements in the connector zone can be connected using elastic couplings.

It is preferable to make a connector that divides the structure into two tiers in such a way that it is formed between two rectangular congruent contours of inflatable longitudinal and transverse cylinders 4 and 8 located along the entire perimeter of the connector in horizontal planes. The first upper balloon 8 of the first congruent contour is connected inseparably with the parts of the inflatable arches 10 and supporting cylinders 9 and completes the separately filled air pneumatic frame of the lower tier 1, and the second rectangular congruent contour is formed by the supporting cylinders 4 of the upper tier 2 and is connected indivisibly with the upper parts of the arches 5, longitudinal 3 cylinders and transverse cylinders of this tier, filled separately from the pneumatic frame of the lower tier.

Detachable interconnecting nodes for connecting the tiers to each other are located on each congruent contour of cylinders mounted on top of each other and include a power 12 and a sealing 13 part, while the power part is made, for example, in the form of flexible contacting congruent contours tightening to full contact around the entire perimeter both tiers, detachable screeds, with one half of 14 detachable screeds located around the perimeter on the upper, final, contour of the lower tier, mainly in the area of the arches, and the second half 15 on a congruent contour around the perimeter of the lower support cylinders 4 of the upper tier opposite the first half of the detachable couplers of the lower tier, and half of the detachable couplers 14 and 15 are interconnected by a flexible element, such as a cord. The sealing part 13 is made in the form of a docking apron from an elastic panel, which is a continuation of the tent 7 of the upper tier, overlapping the power part of the docking in the connector area around the perimeter, while the lower edge of the apron has slots 16 for attachment with fasteners 17 to the panel of the tent 11 of the lower tier.

To create stability against the effects of wind load, the pneumatic frame structure is attached to the ground using anchor pins 18, stretch marks 19 of the lower tier.

The lower part of the pneumatic frame structure is attached to the ground behind the fastening canopy 20 protruding around the entire perimeter of the structure, having holes for anchor pins located along the canopy.

The filling of the pneumatic frames of the upper and lower tiers is carried out separately through the valves 21 and / or tubes 22 mounted in the supporting cylinders 4 and 9.

To ensure life and the necessary conditions for working in a pneumatic frame structure, there are flexible sleeves 23 for laying an electric cable and sleeves 24 for connecting a heat ventilation installation 25.

In one embodiment, see Fig. 10, 11, 19, the use of a pneumoframe structure in the lower or upper tier can be performed at least one section between the closest in height two circuits around the entire perimeter, limited by longitudinal and transverse cylinders and sections arcs isolated by filling due to internal partitions 26 from adjacent sections of the tier. In the unfilled state, the sections of this section are laid by rolling between the inflatable contours of the longitudinal and transverse cylinders, which become the closest in height, which are in contact with each other through the unfilled section of this section and are secured with detachable mating nodes 12, similar to demountable mating nodes located in the connector (separation) zone of the structure on tiers. The unfilled section of the insulated section can be bent into the structure and also fixed.

To increase the bearing capacity of the arches of the pneumoframe structure, some of them inside the upper tier in the upper part can be fastened with horizontally located elastic extensions 27.

For entry or exit from the construction equipment - cars, cranes, on the side end surfaces made of inflatable balloons end doorways 6, also having a connector in the zone of separation of tiers. The doorway is blocked by releasable curtains 28 or another design that provides overlapping input-output. In the embodiment shown in FIGS. 3, 7, 8, the blinds 28 are lifted to provide entry and exit by a cable 29 attached to a light rod 30 located in a pocket along the entire length of the lower edge of the blind 28. Fasteners 17 are disconnected before lifting located on the vertical sides of the curtains and vertical cylinders of the doorway

The pneumoframe structure can have in the base not only a rectangular or square shape, but also others, for example, hexagonal or octagonal, as shown in Figs. 12, 13. There can also be a circle at the base of the structure. Fundamentally, the separation of such options of a pneumatic frame structure into tiers does not differ, it is preferable not to connect each arch or pillar located in vertical planes separately, for example, using devices such as elastic couplings, but to make a connector between congruent horizontal contours of inflatable balloons with similar detachable nodes described in the construction of the structure with a rectangular support contour in plan.

In order to increase the cost-effectiveness of the structure for individual cases of operation, it is acceptable and the option of creating longline structures not over the entire supporting area of the structure, but only over a separate section, for example, in the center of the structure, as shown in Figs. 15, 16, 17, for a pneumatic frame tent structure type. The height-height connector with tiering is also fundamentally formed between congruent horizontal contours of inflatable balloons. In certain operating conditions of a large-sized pneumoframe structure and in order to ensure the manufacturability of its manufacture, there may be a need to create a structure of more than two-tier structures in height, one of such solutions is shown in Fig. 18 - a three-tier pneumoframe structure having a lower tier 1, an upper tier 2 and the intermediate tier 31 with a similar design parallel to the abutted nodes in horizontal planes.

In some embodiments, the filling of the upper tier 2 can be carried out through hoses 32 connecting the support cylinders 4 of the upper tier and 9 of the lower tier into a single system and allowing filling of the tier carcasses sequentially or independently.

The operation of the pneumatic frame structure is as follows.

After receiving the assignment about the location (deployment), they deliver any type of transport of the pneumoframe structure with the necessary equipment, compactly packed in airtight covers. It is possible to use, for example, radio-controlled cargo parachute platforms when landing in hard-to-reach places.

For the installation of a pneumatic frame structure, a place is chosen taking into account the location of underground storage facilities, bunkers, trenches, etc. The structural parts of the structure — the lower tier and the upper tier — are removed from the covers, unfolded, connected to each other in the connector area by docking assemblies, the air blower unit, also included in the support system, is connected to the inlet valve 21 or pipe 22. First, the pneumatic frame of the lower tier is filled to the working pressure, then fill the pneumatic frame of the upper tier, correct the alignment of the installation of the upper tier over the lower, control the congruent contours of the connector, control the uniform tension of the tents 7 and 11. iksiruyut the pneumatic structure to the ground pins 18, pulling the fastening canopy 20.

To prevent displacement from wind loads, the pneumatic frame structure along the side surfaces of the structure is fixed with stretch marks 19 of the lower tier.

The construction is ready for operation and through the open curtains 28 of the doorway 6, lifting means, for example, a truck crane and vehicles for receiving cargo, can call in.

The work can be carried out in a comfortable temperature mode when starting heat ventilation units 25.

During the operation of the pneumatic frame structure, a change of weather may occur, which will lead to an increase or decrease in excess pressure in the pneumatic frame. If the overpressure increases above the permissible value, air is vented through the safety valve, and when the pressure decreases, an automatic air-blowing unit is activated and brings the overpressure of the pneumatic frames of the upper and lower levels to the working one. Maintaining excess pressure in the pneumatic frame can also be carried out using a foot pump. In the event of damage to the pneumatic frames, the air blower installation continues to operate continuously.

The dismantling of the pneumatic frame structure is performed in the reverse order.

If there is a need for a more rational use of energy resources for heating, ventilation, for example, during the absence of lifting equipment in the structure, use the option of reducing the height of the structure by disabling one of the isolated sections of the tier, fixing the laying of the deflated section inside the structure, or between congruent contours of tiers.

In individual cases of operation, when working with small loads without lifting equipment, a pneumoframe structure only from the upper tier can be used, and the lower tier fence without an upper cover for specific operating conditions can be installed separately.

The proposed design of the pneumoframe structure, divided into two tiers, can be produced in industrial production at RTI plants using conventional equipment, equipment and devices, and from known serial materials using existing technology. The pneumoframe construction of the proposed design does not require any special qualifications and knowledge of its manufacturers and the personnel serving it during assembly and operation.

Dividing the structure into tiers makes its production technologically advanced and ensures easy transportability of parts of the structure, although a prototype of the rectangular construction plan made (developed) at the enterprise on the instructions of the Kurchatov Institute had the following overall dimensions: width of the structure - 8.8 m, length - 10.8 m, the maximum height of both tiers is 5.5 m with a doorway height of 3.2 m and an opening width of 4.0 m, the weight of both tiers is not more than 350 kg.

If it is necessary to increase the length of the structure to the end surfaces, the congruent arches can be joined by a similar design of a pneumoframe two-tier structure using detachable lock devices on congruent arches, and the design of lock devices can be similar to the design of detachable lock devices in the tier dividing structure.

The proposed design of the pneumatic frame structure allows you to create comfortable working conditions inside the structure, it has smooth shapes on the outside, which reduces the influence of external factors (increases aerodynamic performance and weather resistance) on the stability of the structure, while the nodes of the tiers are made so that in extreme conditions it can be quickly , without difficulty, to self-assemble from individual tiers a pneumoframe structure that allows it to be operated in any climatic zones, with max mal insulation space from the impact of external factors.

The pneumoframe structure can withstand wind loads of up to 15 m / s and snow cover of up to 5 kg / m ² .

Using a double layer of the tent cover, the possibility of operating the structure in areas of any climatic zone with a temperature of -45 to 50 ° C is achieved. Providing the necessary working conditions is achieved by the equipment attached to the pneumatic frame construction, which makes it possible to operate the entire complex autonomously.

The created climatic conditions inside the structure allow maintenance personnel to work in normal mode without feeling any discomfort.

Thus, the created design of the pneumatic frame structure allowed to reduce the complexity in the manufacture and installation of the structure, ensured the creation of transportable parts of it, and at the same time created the conditions for temporary work inside the structure using large-sized lifting equipment.

Claims (7)

1. Pneumoframe structure, consisting of a pneumatic frame formed by the contour of the supporting inflatable balloons around the perimeter of the structure, inflatable balloons located in other horizontal planes of the structure, connected to inflatable elements such as pillars or arches located in vertical planes, and with inflatable elements that limit the door openings, and the entire pneumatic frame is covered with an elastic material forming an awning, and has a device for changing the overall dimensions of the pneumoframe of the structure, characterized in that the pneumatic frame and the tent are made height-height, at least in one horizontal plane of the connector, dividing them into at least two tiers, and the device for changing the overall dimensions of the structure is made in the form of a system of releasably joined pneumatic frame assemblies and an awning located in the horizontal plane around the entire perimeter of the connector, one part of each of which is attached to the upper part of the lower tier, and the second part of them is to the lower part of the upper tier, comb m the perimeter of the upper part of the lower tier and the equal perimeter of the lower part of the upper tier is made less than or equal to the perimeter of the pneumoframe structure at its base, and the connector is located at least in the part of the structure, mainly in the central one. 2. The pneumoframe structure according to claim 1, characterized in that the connector dividing the structure into two tiers is formed between two congruent circuits of inflatable balloons located in horizontal planes around the entire perimeter of the connector, the first of which is connected inextricably with the struts of inflatable balloons and with supporting cylinders and completes a separately filled pneumatic frame of the lower tier, and the second is formed by supporting cylinders of the upper tier and is inseparably connected with the upper parts of inflatable racks or arches and with other inflatable cylinders of this tier, filled separately from the pneumatic frame of the lower tier, and detachably mating nodes of connecting the tiers between themselves are located on each congruent circuit of cylinders mounted on top of each other, and include a power and sealing part, while the power part is made in the form of flexible tightening up to full contact along the entire perimeter of the contacting congruent contours of both tiers of detachable screeds, with one half of the detachable screeds located around the perimeter on the upper, final, contour of the lower tier , mainly in the area of the inflatable struts, and the second half on the congruent contour around the perimeter of the lower support cylinders of the upper tier, opposite the first half of the detachable screeds of the lower tier, and the sealing part is made in the form of a docking apron made of elastic cloth, which is a continuation of the tent of the upper tier, overlapping the power part of the docking in the area of the connector along the entire perimeter, while the lower edge of the apron has fasteners for attaching to the canvas tent of the lower tier. 3. The pneumoframe structure according to claim 1, characterized in that at least one section is made in the lower or upper tier between the two closest horizontal contours along the entire perimeter, limited by inflatable balloons and sections of inflatable struts or arcs, isolated by filling due to internal partitions of inflatable struts or arcs from adjacent sections of the tier, and in an unfilled state, sections of this section are laid with a skating rink between the inflatable balloon horizontal contours that become the closest in height in which contact each other through the unfilled portion are releasably secured sections and abutting units, detachably joinable same nodes located in a separation zone into tiers structures. 4. Pneumoframe structure according to claim 1, characterized in that the ratio of the heights of the lower and upper tiers is selected in the range of 0.8-1.2. 5. The pneumoframe structure according to claim 1, characterized in that the diameters of the inflatable support cylinders, pillars or arches of the upper tier carcass are chosen equal to or smaller than the diameters of the inflatable support cylinders, struts of the lower tier carcass. 6. Pneumoframe structure according to claim 1, characterized in that the inflatable struts of the lower tier are located to a horizontal plane inside the structure at an angle of 90 ° or less. 7. The pneumoframe structure according to claim 1, characterized in that at least individual inflatable arches or inflatable pillars of the upper tier have inner horizontal elastic stretch marks in the upper part.

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